Logotype-machine.



No. 796,825. PATENTED AUG. 8, 1905.

P. T. DODGE.

LOGOTYPE MACHINE.

APPLICATION FILED NOV. 23. 1904.

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PATENTED AUG. 8, 1905.

P. T. DODGE. LOGOTYPE MACHINE.

APPLICATION FILED Nov. 2s. 1904.

6 SHEETS-SHEET 2.

No. 796,825. PATBNTED AUG. 8, 1905. P. T. DODGE.

LOGOTYPE MACHINE.

APPLIGATlON IILBD NOV. 23, 1904.

6 SHEETS-SHEET s.

H -am ll /l l No. 796,825. PATENTED AUG'. 8, 1905. P. T. DODGE.

LOGOTYPE MACHINE.

APILICATION FILED NOV. 23, 1904.

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No. 796,825. PATENTED AUG. 8, 1905. P. T. DODGE.

LOGOTYPE MACHINE.

APPLICATION FILED NOT. 23, 1904.

6 SHEETS-SHEET 5.

(llinuau n AVM' mnngw. s. annum ca. Move-uwnnnwsns, wAswNcra 6 No. 796,825. PATENTED AUG. 8, 1905. P. T. DGDGE. LO-GOTYPB MACHINE.

APPLICATION FILED NOV. 23, 1904.

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out or justify the line.

UNITED smiles PATENT OFFICE.

VPHILIP T. DODGE, OF BROOKLYN, NEW7 YORK, ASSIGNOR TO MERGEN- THALER LINOTYPE COMPANY, A CORPORATION OF NEW YORK.

LcvcaoTYiDE-lvlACi-iINE.

Specification of Letters Patent.

latented Aug. 8, 1905.

Application filed November 23, 1904. Serial No. 234,069.

To @ZZ whom, it ntcty concern:

Be it known that L PHILIP T. DODGE, of Brooklyn, county of Kings, and State of New York, have invented a new and useful 1mprovement in Logotype-Machines, of which the following is a specification.

1n the commercial Mergenthaler linotypemachine, such as represented in United States Letters Patent No. 557, O00, the matrices representing the individual characters for an entire line of print are assembled in line with wedge spacers, the spacers adjusted to elongate and justify the line, and the line applied momentarily to close a slotted mold in which a continuouslinotype or line-printing slug is cast against the matrices.

The aim of myinvention is to adapt the linotype-machine by a simple modification to produce justified lines of logotypes, the spaces between the words to effect justification being formed integral with the'logotypes. '1`o this end 1 preserve the general organization of the machine; vbut instead of casting a single slug or linotype from the entire justified line of matrices] subdivide the line after composition and justification into word groups and present these groups one at a time to the mold in order to produce a succession of logotypes, the mold being automatically adjusted to a length representing each word plus the space necessary to separate it from the next word.

1n my improved machin-e the matrices and spacers may be held in their ordinary magazines and assembled in line by the ordinary keyboard and escapement mechanism and the wedge spacers adjusted through the line as usual to justify the same to the predetermined length.

The expansion of the line islimited by jaws or abutments, so that the advance of the wedge spacers endwise through the line is limited by the total amount of space required to fill I utilize this limitation of the advance of the spacers to control the adjustment of the mold in order that it may add automatically to the slugs or logotypes cast therein blank portions or spaces of suitable width for the justification of the line.

After the logotypes have been cast the matrices and spacers may be returned to the magazine by the ordinary elevating and distributing mechanisms. Inasmuch as the assembling and distributing mechanisms are not of my invention and may be of ordinary construction, I have limited the drawings herein to those parts of the machine which are necessary to an understanding of my improvement.

Referring to the drawings, Figure 1 is a front view of the mechanism for receiving and justifying the composed line of matrices and forsubdividing the line and casting therefrom the logotypes with justifyingfspaces thereon. Fig. 2 is a vertical section through the elevator or presentation slide on the line 2 2 of the preceding figure. Fig. 3 is a horizontal section on theline 3 3 of the preceding figure, showing particularly the means for limiting the expansion of the matrixline and foroperatingthe justifying-wedges. Fig. LLis aside elevation of the elevator for carrying the groups of matrices successively to the mold looking in the direction of the arrowli in Fig. 1. Fig. 5 is a horizontal section through the elevator on the line 5 of Figs.. 1, 2, and 4. Fig. 6 is avertical section on the line 6 6, Fig. 1. Fig. 7 is a rear View of the mechanism for resetting the mold-adjusting wedge. Fig. 8 is a detail view of one of the parts shown in the preceding figure. Fig. 9 is a rear view of the adjustable mold and attendant parts. Fig. 91L is a horizontal section through the mold and adjacent parts with a group of matrices in operative position. Fig. 9" is an elevation of a word group of matrices and the adjacent spacer as presented to the mold. Figs. 10, 11, and 12 are verticai sections on the correspondingly-numbered lines of Fig. 9. Figs. 13 and 14 are respectively an edge view and a plan view of the adjustable mold-liner for determining the length of the logotype. Fig. 15 is a front elevation of the mold, its carrying-wheel, and parts of the driving mechanism controlling the action of the various cams. Fig. 16 is a diagram illustrating the relations of the various cams and operative parts. Fig. 17 is a side View of a cam and mechanism for shifting the matrix-line. Figs. 18, 19, and 2O are sectional elevations, looking' in the direction of the arrow from the line 18 13, Fig. 15, showing various parts in their different positions. Figs. 21, 22, 23, and 2e are diagrams illustrating the movements of the prin cipal parts for handling the matrices and adjusting the mold. Fig. '25 is a plan view of one of the logotypes and of a device for ejecting the same from the mold. Fig. 26 is a perspective view of a line of logotypes, the product of the machine.

I employ as the basis of the machine the individual letter-matrices and the expansible spacers consisting of two oppositely-tapered wedges connected by sliding joints, as shown and described in United States Letters Patent No. 436,532 and used in the commercial linotype-machines of the present day.

Referring to the drawings, A represents the assembling-elevator, such as used in the linotype-machine, its upper end being horizontally channeled to receive the matrices B and wedge spacers C, as shown in the various gures.

The matrices and spacers will be stored in magazines and assembling devices employed for delivering the matrices and spacers successively to the assembler A, as in the ordinary linotype-machine.

D' represent two fingers depending from horizontal slides mounted in the main frame and connected by a contractile spring D2, which tends to draw the fingers together. These parts constitute what is commonly known as the transfer-carriage of a linotype-machine.

After the composition of the line in the assembler A is completed it is lifted in the ordinary manner to carry the line upward between the lingers D D', as shown by dotted lines in Fig. 1. During this action the fingers D D' are held apart in the usual manner, so that the line may ascend freely between them. As the assembler completes its upwardmovement the pin thereon raises a detaining-catch E out of engagement with the linger D', allowing the latter to move to the left until the line is confined between the two fingers D D', both of which are then moved to the left by the usual operating devices in order to carry the line out of the assembler A and into a stationary channel or support F, as shown in Fig. 1, this channel being known in the linotype-machine as the intermediate channel. While the line of matrices and spacers is thus seated in the intermediate channel and at rest the frame G, having two upright side arms, rises (see Fig. 21) and embraces the arms D D of the transfer-carriage in order to limit their separation, and thereby determine the length of the line when justified. While the parts are in this position the justifying-slide H, guided in the main frame, rises and pushes the wedge spacers C upward through the matriX-line, causing them to justify or elongate the line to the prescribed length. The confnementof the matrix-line endwise limits the separation of the matrices by the spacers, so that the matrices in turn limit the rise of the spacers through the line. ln other words, the resistance or' the matrices arrests the advance ofthe spacers as soon as the line is filled out tightly between the conlining devices. The distance to which the spacers can advance through the line depends not only on the extent to which the line requires to be elongated, but also on the number of words and spaces in the line, and this because the total shortage of the line must be divided by the number of word-spaces-that is to say, by the number of words in the line less one. I therefore util ize the limited advance of the spacers to control the adjustment ot' the mold in order that it may add to the logotypes for each line beyond the type characters thereon extensions or blank spaces appropriate to that line. This result is secured by providing the space-driving slide H with an arm L, arranged to lift an upright wedge J, which in turn acts, as shown in Figs. 9. 11, and 14, to adjust a sliding liner or plate k3, forming one end ot' the slot or cell in the mold K and serving to change the length of the slot and of the logotype cast therein. This adjustment of the mold is independent of the adjustment to the length of the word, which will be presently explained, and is solely Jfor the purpose of securing justiication.

The wedge J consists, as shown in Figs. 9, 9, 13, and 14, of a bar with parallel sides having on opposite sides ribs standing' in an inclined or oblique position. The bar or wedge is guided in a groove in the mold-disk and extended through the mold. The inclined ribs are seated in the sliding liner if, as shown in Figs. 9, 11, and 14, so that although the body of the wedge or bar .slides vertically and without lateral motion the ribs on its edges act with wedging ell'ect to more the liner 1 forward or backward.

lt will be understood, of course. that the opening through the stationary part of' the mold is of such size that the inclined ribs ot' the wedge membcrdo not engage therein, the engagement being limited to the movable liner.

The mold Kis mounted in a vertical intermittingly-rotated wheel L, by which the mold is presented alternately at thc casting and at the ejecting positions, as in the linotype-machine. The mold presents a horizontal slot or mold proper, open at both front and rear, so that when closed on one side by the matrices representing a word it may receive molten metal at the opposite side from a cooperating pot and pump, as in the linotypemachine.

'lhe mold consists of a lower lixed member c, an upper member u', arranged to slide endwise and provided with a shoulder forming one end of the slot or cell, and the sliding intermediate liner la, already referred to, forming the opposite side of the cell. A spring is connected with the sliding mold-top a and tends to move the same to the left for the purpose of shortening the mold-slot. A springactuated dog mounted on the mold-wheel, engages the sliding member and holds the same normally in its extreme position to the right. In this position of the parts the moldslot is of its extreme length, adapted to form a logotype bearing the longest word plus the widest space required for justification. This sliding member of the mold carries also a front projecting jaw 0r abutment 'fs, intended to bear against one end of the matrix-line when 'it is presented t0 the mold to assist in confinwithout disturbing the position of the Wedge .l or the mold-liner, which parts are fitted with sufficient friction to cause them to remain in position. Springs 0r other retaining devices maybe provided, if desired; but they are not deemed essential. The transfer-car-` riage then moves to the left, as shown in Fig. 22. The end of the matrix-line enters the vertically-movable slide or elevator M of the form shown in Figs. 2, 4, and 5 until the advance is arrested by the contact of the first spacing-wedge with the side of the elevator, which is recessed to receive it. In other words, the matrices representing the first word in the line, together with the first spacer, are delivered to the elevator M, as shown in Figs. 9 and 23, with the long wedgeof the spacer in its lowest position. The transfer-carriage then moves with the remaining portion of the line slightly to the right and the elevator M descends, presenting the matrices for the word and the one spacer in front of the mold, as shown in Fig. 23. rlhe line or group of matrices and the spacer are confined between the jaw le on the sliding member of the mold and the adjacent vertical surface on the main frame..

The mold-wheel has, as usual in the linotype-machine, a motion forward and backward in an axial direction. After the matrices are lowered to the casting position the mold advances toward the matrices in order to form a close union with their edges, and at this time the pin lr, protruding from the moldlatch 7c?, encounters an inclined surface lsu on the elevator M, the effect of which is to disengage the dog or latch from the sliding mold member lic', allowing the latter to move endwise under the infiuenee of spring f until the jaw z compresses the line of matrices endwise, thus locking them tightly together in front of the mold-slot.

VIt will be observed that the matrix-confining jaw 7c, bearing against the matrices, limits the motion of the sliding member c', and

thus reduces the mold-slot to a length corresponding with that of the word to be cast, this length being, however, further increased to the extent of the justifying-space required by the prior movement of the liner /f' at the opposite end of the slot.

lhen the wedge J is in its lowermost or normal position, the mold-slot will be 'of a length corresponding exactly with the length of the matrix-line presented, or, in other words, to the length of the wordrepresented by the matrices. It is only when the wedge J is raised and the liner /13 retracted that the logotype is given a length greater than the length of the word thereon.

-\Vhile the matrices are locked in position in front of the mold it will be supplied from the rear with molten metal from the usual melting-pot, as in the linotyjie-machine. The disk and mold are then retracted and the disk given a partial rotation until it is brought opposite the usual ejector-blade N, Fig. 25, which, advancing from the rear, will drive the logotype out of the mold. This ejector is preferably beveled at the end, as shown, in order to act on the slidingl member of the mold and push the same backward until it is again retained by the dog f?, after which the disk continues its rotation and presents the mold again in the casting position. The elevator M next rises from the casting position to carry the contained matrices and spacer to the position shown in dotted lines in Fig. 23, so that they may be transferred to the customary devices of the linotype-machine or equivalent devices for delivering them to the distributers, by which they are returned to the magazines. The elevator then descends to its first position, the transfer -carriage again moves to the left, and the matrices represcnting the second word in the line, together with the second spacer, are transferred to the elevator, which then presents them in turn to the mold, which casts a second logotype with an attached space equal to that produced on the first. peated, the words and following spacers being presented successively to thc mold, which retains its adjustment, so far as the liner f is concerned, until the last word in the line is reached. It is to be noted that although the spacers are carried with the matrices to the mold they are not relied upon to aid in justification or in determining the width of' the spaces cast on the logotype, since they arealways presented in the same position that is to say, with their upper ends adjusted to the minimum thickness. '.lhe matrices representing' this word are presented to the mold in the same manner as the others; but as no justifying-space is required in connection with the last word or logotype the liner 1 must be restored to its inner position before the last logotypeof the line is east. For this purpose l provide mechanism shown in Figs. (S, 7,

'lhese operations are reand 8. The line-transfer carriage is provided with a pin CZ, Fig. 7, and when the carriage reaches its position at the extreme left, delivering the matrices of the last word to the elevator M, this pin strikes a spring-actuated slide CZ', which supports a vertical slide (Z2, acted upon by a weight Z3 and carrying a dog (Z4 to act upon the upper end of the wedge J. The dog or slide d sustains these parts normally in the elevated position shown in full lines in Fig. 6; but when the dog is pushed back by the pin on the transfer-carriage it releases the slide d2, which immediately descends under the influence of the weight, causing the dog d* to act upon the wedge J and return it to its lower position, thereby moving the mold-liner r to its normal or innermost position.

For the purpose of imparting the proper relative movements to the parts as above described I may employ operating devices of any suitable character; but I recommend the construction and arrangement of parts shown in the accompanying drawings and which will now be described.

rlhe line-shifting carriage D D' is moved to and fro, as shown in Fig. 15, by a link 0, attached to the upper end of a lever O, mounted at its lower end on a rock-shaft 02 in the frame. This rock-shaft carries, as shown in Figs. 12 and 15, an arm 03, acted upon by a spring 04, which tends through the intermediate parts to move the line-shifting carriage D D' forward to the left. The shaft also carries a second arm of', acting on the side face of a cam o, secured on a shaft o", this cam serving to move the lever O in opposition to the spring o4 in order to move the line-carriage backwardto the right. The carriage must be moved repeatedly forward and backward to advance the successive groups of matrices toward the devices for transferring them to the mold, and as the carriage must also be restored to its original position at the extreme right, as shown in Fig. 1, to receive the composed line, l therefore provide a second cam 07, which also acts on the crank-arm o", as shown in Figs. 15 and 16. These two cams are driven alternately to effect the proper movements. Motion is imparted to the cams by mechanism shown in Figs. 15 to 18, inclusive. rlhe shaft o, carrying the cam 0G, is provided with a large gearwheel Us, which receives motion through a pinion nl, which in turn receives motion intermittingly from an idle pinion o, carried by a swinging arm u, mounted loosely on the main driving-shaft 01, This shaft is provided with a pinion 01.7 and with a constantly-driven pulley um. Through these parts constant motion is imparted to theidle pinion ou. A spring o, acting on the swinging arm, tends to draw thel idle pinion n into engagement with the pinion 0"" in order to impart motion through the intermediate parts to the cam of. Between Phe second cam 07, has its shaft provided with a large gear-wheel ff", which receives motion from pinion 0'" on a shaft d, carrying a second pinion 023 in position to be engaged by the idler o when it is pulled over to the position shown in Fig. 20. Then the parts are in this position, motion will be transmitted to the cam 07 while the cam o" remains at rest. The disengagement of the idler from pinion 013 to arrest the cam a is automatically effected by pin 02, mounted on the gear a and acting on the upper end of dog or bar 01'" to drive the same downward, as shown in Fig. 19. The movement ofthe arm 0" to throw the second cam 07 into action is effected, as shown in Fig. 20, by the hand-lever 025, connected by link 02G to the arm 01"". When the idleris thus thrown into engagement, the connection is maintained by a latch 027, pivoted to the upper end of arm 0" and engaging a fixed lip of". When the cam completes a revolution ending the cycle of operations, the shoulder 03 thereon encounters the latch or dog d and trips the same out of action, .so that the spring will pull the idler o out of engagement. The dog or latch is moved end wise into the path of the projection on the cam by means of a bell-crank of, connected by link ci toa crankarm of on rock-shaft um. This shaft is provided with a cross-arm of", one end of which carries the controlling-dog ol", before referred to, while the opposite end carries an actuating-rod P, which is extended upward into the path of the line-transfer carriage D D', as shown in Figs. 1 and 15. As the transfer-carriage moves forward an inclined surface d'0 at its rear end depresses the rod P, thereby lifting the dog 0"" and throwing into action the parts for moving the first group of cams, including the cam or. \'V hen the carriage is finally retracted, a second inclined shoulder cl thereon effects a second depression of the rod P, which sets the pinion-controlling dog ou in an intermediate position, as shown in Fig. 19, so that the idler is out of engagement and both sets of cams are permitted to remain at rest.

As the various cams and other details for imparting motion to the minor parts are not of the essence of my invention and not necessary to an understanding of the same, l have omitted them from the drawings; but the manner in which they will be grouped is indicated in Fig. 16. l

The cams for actuating the clamping-frame Gr and the justifying-slide are mounted on the same shaft with cam o and gear 0", while the line-shifting cam, the space-separating cam, ejector-cam, mold-pot and pump cams, distributer-shifter cam, and the elevator-cam belonging to the second group are all mounted on the same shaft with cam o7 and gear 02".

I believe myself to be the first to devise a logotype-machine wherein expansible spacers or justifiers limited in their advance by the resistance of the matrix-line are utilized to control the adjustment of the mold in order to produce upon the logotypes spaces suitable to justify the line, and I also believe myself to be the iii-st to divide a justified line of matrices and expansible spacers and transfer the Word groups, together with the spacers, to the mold, and it is to be understood that I claim such arrangement of parts in any form the mechanical equivalent of that herein described and shown.

Having described my invention, what I claim isl. rIhe combination ofmatrices, expanding spacers and means for assembling the same in line, with means for actuating the spacers to justify the line, an adjustable mold controlled by the actuating device, and means for presenting the Word groups of matrices successively to the mold.

2. The combination of matrices, expanding spacers and means for assembling the same in line, with means for actuating the spacers to justify the line, an adjustable mold controlled by the actuating' device, and means for presenting the Word groups of matrices and the spacers successively to the mold.`

3. In a machine for producing justi lied lines of logotypes, means for assembling matrices and expansible spacers, a mold adjustable in length means for presenting the matrices and spacers jointly to the mold, and means controlled by the spacers to adjust the mold for justilication ot' the line.

4. Ina machine for producing justified lines of logotypes, the combination of matrices, expansible spacers and means for assembling the same in line, means for adjusting the spacers, means forlimiting the length of the line, a mold, means for presenting the word groups of matrices thereto, means for adjusting the mold to correspond with the length of each word, and means controlled by the spacers to further adjust the mold to form justifyingspaces on the logotypes.

5. In a machine for producing justified lines of logotypes, matrices, expansible spacers, and means for assembling the same in line, with means for adjusting the spacers to justify the line, a mold, means for presenting' the Word groups of matrices to the mold, and means controlled by the spacers to adjust the mold to add justifying-spaces to the logotypes.

6. In a logotype-machine, the mold adjustable in length at both ends, in combination with a matrix group arranged to determine the length of the mold at one end, and the Wedge to determine the length from the other end.

'7. In a machine for producing j ustiiied lines of logotypes, the combination of matrices, expansible spacers, the means for assembling' them in line, a mold adjustable in length, means for presenting the word groups of matrices and the adjacent spacers to the mold.

8. In a machine for prod ucing justiiied lines of matrices, matrices, expansible spacers and means for assembling' them in line, in combination with means for adjusting the spacers, means for limiting the length of the line, a mold adjustable in length at both ends, means for presenting' the Word groups of matrices and the following spacers to the mold, means actuated by the matrices to adjust the mold at one end, and means controlled by the spacers to adjust the mold at the other end.

9. The mold adjustable at one end, in combination with a line of matrices, expansible spacers therein, means for dividing the line into Word groups and jn'eseiiting the same to the mold, and means controlled bythe spacers for adjusting the mold; whereby the mold is caused to add to the logotypes cast therein spaces suitable for the justilication of the line.

l0. The combination of the mold, the wedge to vary its length, the line of matrices and spacers, the rmovable frame G, to limit the length of the line, and pusher l'l, for adjusting the spacers and the mold-adj ustin g wedge.

l1. The combination of the carrier for lines of matrices, the elevator.horizontally channeled to receive the matrices and arranged to remove word groups from the niatrix-line, the variable mold arranged to receive said groups, and means for eii'ecting the necessary adjustment of the mold.

l2. In a logotype-machii'ie, a composed line of matrices containing spaces between the word groups, in combination with a variable mold and a carrier adapted to transfer the word groups and spaces to the mold, thespaces being employed to separate the groups from the line at the time of transference.

18. In a logotype-machine,the matrices and expansible spacers, in combination with means for assembling the same in line, means for temporarily expanding the spacers to justify the line, a variable mold, means for presenting the word groups of matrices to the mold, and means controlled by the spacers, for adjusting the mold to form justifying-spaces on the logotypes cast therein.

14. In a logotype-machine, a composed line of matrices and expansible spacers, means for expanding the spacers to justify the line, a mold to form logotypes from the word groups of matrices, 1means controlled by the movement of the spacers to adjust the length of the mold, and means for presenting' the word groups of matrices and the spacers in their contracted form to the mold, whereby the spacers are utilized to effect the adjustment of the mold to produce the justifying-spaces on the logotypes without the direct use of the spacers at the mold for that purpose.

l5, In a logotype-machine, a composed line -of matrices and expanding spacers, means for expanding the spacers temporarily to justify the line, a mold arranged to cooperate with the other groups of matrices, means for adjusting the mold controlled by the adjustment i Witnesses:

of the spacers, and means for presenting the word groups of matrices together with the unexpanded spacers to the mold.

In testimony whereof I hereunto set my hand, this 22d`day of November, 1904:, in the presence of two attesting witnesses.

PHILIP T. DODGE.

JOHN F. GEORGE, VALTER MoBLAnD. 

